KR100970861B1 - Flat type solar heat collector having double vacuum tube - Google Patents

Abstract

PURPOSE: A flat solar collector using a double vacuum tube is provided to improve collecting efficiency and allow for natural circulation of a thermal medium without a circulating pump. CONSTITUTION: A flat solar collector comprises a thermal medium inlet tube(11), a upper tube(20), a thermal medium return tube(12), a lower tube(30), a dual vacuum tube(50), and one or multiple heating tubes. An end of the thermal medium inlet tube is connected to a side of a heat storage tank(10). An end of the upper tube is connected to the other end of the thermal medium inlet tube. An end of the thermal medium water tube is connected to the other side of the heat storage tank. An end of the bottom tube is connected to the other end of the thermal medium water tube. The heating tube is connected to the one side of the upper and the lower tube to connect the internal space of the lower and the upper tube. The dual vacuum tube is installed to cover the exterior of the heating tube, in which a vacuum is made between the outer tube and the inner tube.

Description

Flat type solar heat collector having double vacuum tube

The present invention relates to a flat plate collector using a double vacuum tube, and more particularly, by constructing a flat plate solar collector as a double vacuum tube, it has a higher heat collection efficiency than a conventional flat plate solar collector, and unlike a conventional tube, The present invention relates to a solar heat collector capable of more efficient heat transfer by using a density difference and thus enabling operation without a separate circulation pump, and having a heat transfer plate and having a structure in which the heat transfer plate is closely attached to the vacuum tube.

The solar heat utilization system is a technology used for cooling and heating and hot water supply of buildings by absorbing, storing, and converting solar heat using wave characteristics and photothermal properties of solar rays.

The heat collecting unit plays an important role as a device for absorbing the sun's radiant energy and converting it into renewable heat energy. Generally, the solar heat collecting unit has a condensing type and a non-condensing type.

In the case of condensing type, high temperature heat of 200 ℃ or more can be obtained, but it is mainly used for solar power generation because it requires a lot of initial installation and management costs such as having to provide a solar tracking system.

Non-condensing type is flat type and vacuum tube type,

In the conventional flat solar collector, as shown in FIG. 1, the heating tube 140 is installed on the metal solar heat collecting plate 130, and when the solar heat emitted from the sun is collected on the heat collecting plate 130, the heating tube installed on the heat collecting plate 130 ( The heat medium inside the heat is heated, and the heated heat medium flows into the heat storage tank 100 through the heat medium inlet pipe 110 by the density difference. The heat medium introduced into the heat storage tank 100 is reduced in temperature through mutual heat exchange with cold water, and the heat medium whose temperature is reduced is returned to the heating tube 140 through the heat medium return pipe 120. It is called natural circulation.

The basic solar collector used in such a solar hot water hot water supply system is not only inexpensive but also known as the most efficient collector due to the natural circulation of the heat medium.

In the conventional vacuum tube solar collector, as shown in FIG. 2, the heat transfer plate and the U-shaped heating tube 220 are installed in the vacuum glass tube 210 sealed downward, and the heat acquisition temperature by the heat medium is 80 ° C. to 200 ° C. FIG. It is possible to obtain heat at a higher temperature than the conventional flat solar collector in the range of ℃, but since the heat medium is not naturally circulated, a separate heat medium circulation pump 200 is required and the efficiency is low.

In addition, in the past, the heating tube is directly welded to and fixed to the heat collecting plate, but this is limited to a part where the heat collecting plate and the heating tube contact each other. In addition, when the heating tube is damaged and needs to be replaced, there is a problem such as replacing the welded heat collecting plate together.

The present invention has been made to solve the above problems, an object of the present invention is to use a double vacuum tube that can obtain a high heat collection efficiency in a small area compared to the flat plate type, but the structure does not require a circulation pump as conventional Proposed, it is possible to obtain a high temperature heat more efficiently, to be installed in close contact with the heat transfer plate inside the double vacuum tube, and to increase the heat collecting efficiency by widening the contact area with the heating tube in the heat transfer plate.

The present invention for achieving the above object, the one end of the heat medium inlet pipe coupled to one side of the heat storage tank and one end of any one of the upper end and the other end of the heat storage tank coupled to the other end of the heat medium inlet pipe One end of any one of the heat medium return tube and both ends are combined with the other end of the heat medium return tube and one end is connected to one side of the upper tube, the other end is connected to one side of the lower tube to the inside of the upper tube and the lower tube At least one heating tube communicating with the space and is installed to surround the outer peripheral surface of the heating tube, and includes a double vacuum tube between the outer tube and the inner tube is a vacuum.

Here, it is preferably configured to further include a heat transfer plate which is installed to contact the inner surface of the double vacuum tube, one side of the outer peripheral surface of the heating tube in contact with the inner surface.

In addition, the heat transfer plate is characterized in that one side is cut along the longitudinal direction, the heat transfer plate is formed with a fitting protrusion from the inner surface to the inside, the fitting groove for forming the copper tube is fitted on one side of the fitting protrusion is formed. It is preferable to be.

In addition, the reflector of the circular curved shape in the same direction as the double vacuum tube is preferably installed below the collector.

According to the present invention as described above, it is possible to obtain a high heat with less heat collecting area in a conventional flat plate collector using a double vacuum tube, the dual vacuum tube is configured in the form of a natural circulation collector, the heat medium density without the circulation pump The car can be naturally circulated.

In addition, the heat transfer plate may be installed in close contact with the inside of the double vacuum tube and the contact area with the heating tube in the heat transfer plate may be increased to further increase the heat collecting efficiency.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

Figure 3 is a schematic view of a flat plate collector using a double vacuum tube according to the present invention, Figure 4 is a partial cutaway perspective view, Figure 5 is a partial cutaway cross-sectional view.

The present invention is one end of the heat medium inlet pipe 11 is coupled to one side of the heat storage tank 10 and one end of any one end of the upper tube 20 and one end is coupled to the other end of the heat medium inlet pipe 11 The heat pipe return pipe 12 coupled to the other side of the heat storage tank 10 and one end of either end of the lower pipe 30 and one end coupled to the other end of the heat transfer pipe 12 are connected to the upper pipe 20. At least one heating tube 40 and the heating tube is connected to one side of the), the other end is connected to one side of the lower tube 30 to communicate the inner space of the upper tube 20 and the lower tube (30) It is provided to surround the outer circumferential surface of (40), and is configured to include a double vacuum tube 50 is a vacuum between the exterior and the inner tube.

In addition, the present invention is installed to contact the inner surface of the double vacuum tube 50, it is more preferable to further include a heat transfer plate 70 so that one side of the outer peripheral surface of the heating tube 40 in contact with the inner surface.

In addition, in the present invention, it is preferable to provide a reflecting plate 60 having a circular curved shape in the same direction as the double vacuum tube 50 to absorb the solar heat from the upper side and to reflect or absorb the solar heat.

The heat medium inflow pipe 11 and the heat medium return pipe 12 are connected at one end to one side and the other side of the heat storage tank 10.

One end of each of the upper tube 20 and the lower tube 30 is connected to the other end of the heat medium inlet pipe 11 and the heat medium return pipe 12.

At least one heating tube 40 is connected to one side of the upper tube 20 and the lower tube 30.

When the heat medium inside the heating tube 40 is heated by solar heat, the heat medium heated by the density difference rises and flows into the heat storage tank 10 through the heat medium inlet pipe 20, and the heat medium in the heat storage tank 10. After the hot water and the heat transfer is carried out through heat exchange, the heat medium that loses heat flows back into the heating tube 40 through the heat medium return pipe 30 and circulates.

The material of the heating tube 40 may be a general metal or synthetic resin, but if possible, it may be preferable to use a copper pipe having high thermal conductivity and hardly rusting.

The double vacuum tube 50 is a tube in which a vacuum is formed between the exterior 51 and the inner tube 52 and is made of a transparent material. In general, since the double vacuum tube 50 used for the solar collector should be able to withstand the external atmospheric pressure due to high vacuum, it will usually be preferable to configure the cylindrical shape.

The outer surface of the inner tube 52 of the double vacuum tube 50 may be a selective absorption film coating having a high absorption rate and low emissivity to be treated for efficient absorption of solar heat emitted from the sun.

In addition, the material of the double vacuum tube 50 will be preferable to use a reinforcing material so as not to break even at high temperatures due to absorption of solar heat.

The reflector 60 may be preferably made of a material having a high reflectance in order to efficiently collect heat emitted from the sun. For this purpose, a separate plating treatment or a reflecting film, silver foil, etc. may be applied to the reflector 60 to increase reflectance. It will be possible to process the thin film and attach it using a separate adhesive means.

In general, in the case of solar radiation passing through the double vacuum tube 50, depending on the nature of the reflecting surface, but mostly absorbed or reflected, but rarely the focus is on the double vacuum tube (50). Therefore, by installing a reflecting plate designed to uniformly irradiate the back surface of the double vacuum tube 50 under the solar collector, the solar absorber directly absorbs the solar radiation and reflects and collects the components that are deflected, thereby exhibiting high efficiency of collecting performance.

The heat transfer plate 70 is installed in close contact with the inner circumferential surface of the double vacuum tube 50 and is installed to surround at least one heating tube 40. The material of the heat transfer plate 70 may be a metal or a synthetic resin, but it is reasonable to use a metal having a high heat transfer coefficient.

In addition, the heat transfer plate 70 is one side is cut along the longitudinal direction, when inserted, coupled to the inside of the double vacuum tube 50 is in close contact with the inner peripheral surface of the double vacuum tube 50 is coupled. In addition, the heat transfer plate 70 is configured so that at least one or more fitting protrusions 71 are formed inward from the inner surface, and a fitting groove in which the heating tube 40 is forcibly fitted on one side of the fitting protrusion 71 is formed. By inserting the heating tube into the fitting groove, the contact surface between the heat transfer plate 70 and the heating tube 40 is widened, and the heat collected in the double vacuum tube 50 is transferred to the inside of the heating tube 40 through the heat transfer plate 70. It is more efficiently delivered to the heating medium in.

Hereinafter, the operation of the present invention having the configuration as described above will be described.

Solar heat emitted from the sun passes through the exterior 51 of the double vacuum tube 50 and is collected on the outer surface of the coated inner tube 52. Heat collected on the outer surface of the inner tube 52 is conducted to the heating tube 40 through the heat transfer plate 70 and heats the heat medium in the heating tube 40.

The heat medium whose temperature is raised rises to the top of the heating tube 40 due to the density difference, and flows into the heat storage tank 10 through the heat medium inlet pipe 10. The heat medium introduced into the heat storage tank 10 exchanges heat with cold water flowing in the heat storage tank 10 to supply the thermal energy of the heat medium to the cold water. The heat medium cooled by the mutual heat exchange is re-supplied to the heating tube 40 through the heat medium return pipe 30.

As shown in FIG. 5, in the present invention, the use of the double vacuum tube 50 having one or more layers of vacuum portions 53 receives heat from the sun and collects the heat from the surface of the double vacuum tube 50. This is because the heat medium whose temperature rises in the state in which the heat medium is filled is advantageous for keeping warm for a long time because heat is insulated from the outside air by the vacuum part 53.

Figure 6 is a partial cutaway perspective view of a flat plate collector using a double vacuum tube according to the present invention.

The present invention may include a housing (80) wrapped around the upper tube (20), the side of the housing (80) has a hole for fitting a double vacuum tube, the packing member 90 for fixing the double vacuum tube (50) It can be configured to include.

The housing 80 may be configured to include a heat insulating material wrapped around the upper tube 20 inside.

The packing member 90 may be configured as a screw / bolt coupling,

The housing 80 and the heat insulating material and the packing member 90 can be configured in the same way as the lower tube (30).

1 is a schematic view of a flat solar collector according to the prior invention.

Figure 2 is a schematic diagram of a vacuum tube solar collector according to the prior invention.

Figure 3 is a schematic diagram of a flat plate collector using a double vacuum tube according to the present invention.

Figure 4 is a partial cutaway perspective view of a flat plate collector using a double vacuum tube according to the present invention.

Figure 5 is a partial cutaway cross-sectional view of a flat plate collector using a double vacuum tube according to the present invention.

Figure 6 is a partial cutaway perspective view of a flat plate collector using a double vacuum tube according to the present invention.

10: heat storage tank 11: heat medium inlet pipe

12: heat medium return pipe 20: upper pipe

30: lower tube 40: heating tube

50: double vacuum tube 51: appearance

52: inner tube 53: vacuum portion

60: reflector 70: heat transfer plate

71: fitting protrusion 80: housing

90: packing member

Claims (4)

In the flat type solar collector which communicates with the heat storage tank and flows heat in and out, A heat medium inlet pipe having one end coupled to one side of the heat storage tank; An upper tube having one end of either end coupled with the other end of the heat medium inlet pipe; A heat medium return pipe having one end coupled to the other side of the heat storage tank; A lower tube having one end of either end coupled to the other end of the heat medium return tube; At least one heating tube having one end connected to one side of the upper tube and the other end connected to one side of the lower tube to communicate an inner space of the upper tube and the lower tube; And a double vacuum tube installed to surround the outer circumferential surface of the heating tube and having a vacuum between the exterior and the inner tube. The method of claim 1, It is installed to contact the inner surface of the double vacuum tube, a flat plate collector using a double vacuum tube, characterized in that it further comprises a heat transfer plate so that one side of the outer peripheral surface of the heating tube in contact with the inner surface. 3. The method of claim 2, The heat transfer plate is characterized in that the one side is cut along the longitudinal direction, the heat transfer plate is formed in the fitting protrusion from the inner surface, the fitting groove for forming the heating tube is fitted on one side of the fitting protrusion is formed. Flat collector using a double vacuum tube, characterized in that. The method of claim 1, A flat plate collector using a double vacuum tube, characterized in that a reflecting plate of a circular curved shape in the same direction as the double vacuum tube is installed on the lower side of the collector.

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